* sorta working in runtime
* wasmtime-runtime: get rid of wasm-backtrace feature
* wasmtime: factor to make backtraces recording optional. not configurable yet
* get rid of wasm-backtrace features
* trap tests: now a Trap optionally contains backtrace
* eliminate wasm-backtrace feature
* code review fixes
* ci: no more wasm-backtrace feature
* c_api: backtraces always enabled
* config: unwind required by backtraces and ref types
* plumbed
* test that disabling backtraces works
* code review comments
* fuzzing generator: wasm_backtrace is a runtime config now
* doc fix
This is required now that the simd specification has been merged into
the upstream specification, so to run the spec tests this must always be
enabled instead of being left to the whims of the fuzzer about whether
to enable it or not.
* Update the wasm-tools family of crates
This commit updates these crates as used by Wasmtime for the recently
published versions to pull in changes necessary to support the component
model. I've split this out from #4005 to make it clear what's impacted
here and #4005 can simply rebase on top of this to pick up the necessary
changes.
* More test fixes
* Update to clap 3.0
This commit migrates all CLI commands internally used in this project
from structopt/clap2 to clap 3. The intent here is to ensure that we're
using maintained versions of the dependencies as structopt and clap 2
are less maintained nowadays. Most transitions were pretty
straightforward and mostly dealing with structopt/clap3 differences.
* Fix a number of `cargo deny` errors
This commit fixes a few errors around duplicate dependencies which
arose from the prior update to clap3. This also uses a new feature in
`deny.toml`, `skip-tree`, which allows having a bit more targeted
ignores for skips of duplicate version checks. This showed a few more
locations in Wasmtime itself where we could update some dependencies.
This makes the generator more similar to `wasm-smith` where it is keeping track
of what is on the stack and making choices about what instructions are valid to
generate given the current stack state. This should in theory allow the
generator to emit GC calls while there are live refs on the stack.
Fixes#3917
The documentation for the `wasm-spec-interpreter` was not up-to-date,
causing some confusion on non-Ubuntu machines. This change adds the
correct dependencies to install and includes the `libgmp` path for
Fedora by default (i.e., `/lib64`).
* Update wasm-tools crates
This commit updates the wasm-tools family of crates as used in Wasmtime.
Notably this brings in the update which removes module linking support
as well as a number of internal refactorings around names and such
within wasmparser itself. This updates all of the wasm translation
support which binds to wasmparser as appropriate.
Other crates all had API-compatible changes for at least what Wasmtime
used so no further changes were necessary beyond updating version
requirements.
* Update a test expectation
* Upgrade all crates to the Rust 2021 edition
I've personally started using the new format strings for things like
`panic!("some message {foo}")` or similar and have been upgrading crates
on a case-by-case basis, but I think it probably makes more sense to go
ahead and blanket upgrade everything so 2021 features are always
available.
* Fix compile of the C API
* Fix a warning
* Fix another warning
* Remove the module linking implementation in Wasmtime
This commit removes the experimental implementation of the module
linking WebAssembly proposal from Wasmtime. The module linking is no
longer intended for core WebAssembly but is instead incorporated into
the component model now at this point. This means that very large parts
of Wasmtime's implementation of module linking are no longer applicable
and would change greatly with an implementation of the component model.
The main purpose of this is to remove Wasmtime's reliance on the support
for module-linking in `wasmparser` and tooling crates. With this
reliance removed we can move over to the `component-model` branch of
`wasmparser` and use the updated support for the component model.
Additionally given the trajectory of the component model proposal the
embedding API of Wasmtime will not look like what it looks like today
for WebAssembly. For example the core wasm `Instance` will not change
and instead a `Component` is likely to be added instead.
Some more rationale for this is in #3941, but the basic idea is that I
feel that it's not going to be viable to develop support for the
component model on a non-`main` branch of Wasmtime. Additionaly I don't
think it's viable, for the same reasons as `wasm-tools`, to support the
old module linking proposal and the new component model at the same
time.
This commit takes a moment to not only delete the existing module
linking implementation but some abstractions are also simplified. For
example module serialization is a bit simpler that there's only one
module. Additionally instantiation is much simpler since the only
initializer we have to deal with are imports and nothing else.
Closes#3941
* Fix doc link
* Update comments
In today's installment of the Wondrous Adventures of What Are the Actual
Limits on the Pooling Allocator Required to Run the Spec Tests a fuzz
bug was found where the instance size wasn't big enough to run
`names.wast`. Today's episode is similar to prior episodes where a limit
is bumped until the test passes.
A recently discovered fuzz bug reported a difference in execution result
between Wasmtime and v8. The module in question had an exported function
which had multiple results, including floats. About a year ago I
reported a bug on v8 about functions with multiple results leading to
incorrect results, and it was fixed many months back but I don't think
that we ever actually pulled in that update. After updating v8 I saw the
test failure go away, so this update is being done to fix the fuzz bug
test failure I saw.
* Delete historical interruptable support in Wasmtime
This commit removes the `Config::interruptable` configuration along with
the `InterruptHandle` type from the `wasmtime` crate. The original
support for adding interruption to WebAssembly was added pretty early on
in the history of Wasmtime when there was no other method to prevent an
infinite loop from the host. Nowadays, however, there are alternative
methods for interruption such as fuel or epoch-based interruption.
One of the major downsides of `Config::interruptable` is that even when
it's not enabled it forces an atomic swap to happen when entering
WebAssembly code. This technically could be a non-atomic swap if the
configuration option isn't enabled but that produces even more branch-y
code on entry into WebAssembly which is already something we try to
optimize. Calling into WebAssembly is on the order of a dozens of
nanoseconds at this time and an atomic swap, even uncontended, can add
up to 5ns on some platforms.
The main goal of this PR is to remove this atomic swap on entry into
WebAssembly. This is done by removing the `Config::interruptable` field
entirely, moving all existing consumers to epochs instead which are
suitable for the same purposes. This means that the stack overflow check
is no longer entangled with the interruption check and perhaps one day
we could continue to optimize that further as well.
Some consequences of this change are:
* Epochs are now the only method of remote-thread interruption.
* There are no more Wasmtime traps that produces the `Interrupted` trap
code, although we may wish to move future traps to this so I left it
in place.
* The C API support for interrupt handles was also removed and bindings
for epoch methods were added.
* Function-entry checks for interruption are a tiny bit less efficient
since one check is performed for the stack limit and a second is
performed for the epoch as opposed to the `Config::interruptable`
style of bundling the stack limit and the interrupt check in one. It's
expected though that this is likely to not really be measurable.
* The old `VMInterrupts` structure is renamed to `VMRuntimeLimits`.
When using the pooling instance allocator for running spec tests we have
to make sure that the configured limits of the allocator aren't so low
as to cause the spec tests to fail due to resource exhaustion issues or
similar. This commit adds in minimum thresholds for instance size as
well as instance count. While here this goes ahead and refactors
everything here to look similar.
* fuzz: Fuzz padding between compiled functions
This commit hooks up the custom
`wasmtime_linkopt_padding_between_functions` configuration option to the
cranelift compiler into the fuzz configuration, enabling us to ensure
that randomly inserting a moderate amount of padding between functions
shouldn't tamper with any results.
* fuzz: Fuzz the `Config::generate_address_map` option
This commit adds fuzz configuration where `generate_address_map` is
either enabled or disabled, unlike how it's always enabled for fuzzing
today.
* Remove unnecessary handling of relocations
This commit removes a number of bits and pieces all related to handling
relocations in JIT code generated by Wasmtime. None of this is necessary
nowadays that the "old backend" has been removed (quite some time ago)
and relocations are no longer expected to be in the JIT code at all.
Additionally with the minimum x86_64 features required to run wasm code
it should be expected that no libcalls are required either for
Wasmtime-based JIT code.
A recent fuzz failure showed that at least `call.wast` requires a memory
larger than 10 pages, so increase the minimum number of pages that can
be used for executing spec tests.
If either end stack overflows we can't validate the other side since the
other side, depending on codegen settings, may have been successful, hit
a different trap, or also stack overflowed.
Another instance similar to #3879 where when doing differential tests
the pooling allocator configuration needs to be updated to allow for a
possible table.
* Move spec interpreter fuzzing behind a Cargo feature
Building the spec interpreter requires a local installation of Ocaml and
now libgmp which isn't always available, so this enables the ability to
disable building the spec interpreter by using `cargo +nightly fuzz
build --no-default-features`. The spec interpreter is still built by
default but if fuzzers are being built locally and the spec interpreter
isn't needed then this should enable it to be relatively easily
opted-out of.
* Tweak manifest directives
The recent removal of `ModuleLimits` meant that the update to the
fuzzers could quickly fail where the instance size limit was set to
something small (like 0) and then nothing would succeed in compilation.
This allows the modules to fail to compile and then continues to the
next fuzz input in these situations.
This seems to have intended to allow overrides but the specific Makefile
syntax used didn't actually allow overrides, so update that to allow env
vars from the outside world to override the variable (needed locally on
AArch64 I'm building on which has a different path to libgmp)
Spec tests require multi-value to be enabled and wasm-smith recently
made this a fuzz-input option, so override the fuzz input as we do for
other features and force-enable multi-value.
This commit updates the build script which clones the spec interpreter
for fuzzing to specifically pin at a hardcoded revision. This is
intended at improving reproducibility if we hit any issues while fuzzing
to ensure that the same wasmtime revision is always using the same spec
interpreter revision.
* Remove the `ModuleLimits` pooling configuration structure
This commit is an attempt to improve the usability of the pooling
allocator by removing the need to configure a `ModuleLimits` structure.
Internally this structure has limits on all forms of wasm constructs but
this largely bottoms out in the size of an allocation for an instance in
the instance pooling allocator. Maintaining this list of limits can be
cumbersome as modules may get tweaked over time and there's otherwise no
real reason to limit the number of globals in a module since the main
goal is to limit the memory consumption of a `VMContext` which can be
done with a memory allocation limit rather than fine-tuned control over
each maximum and minimum.
The new approach taken in this commit is to remove `ModuleLimits`. Some
fields, such as `tables`, `table_elements` , `memories`, and
`memory_pages` are moved to `InstanceLimits` since they're still
enforced at runtime. A new field `size` is added to `InstanceLimits`
which indicates, in bytes, the maximum size of the `VMContext`
allocation. If the size of a `VMContext` for a module exceeds this value
then instantiation will fail.
This involved adding a few more checks to `{Table, Memory}::new_static`
to ensure that the minimum size is able to fit in the allocation, since
previously modules were validated at compile time of the module that
everything fit and that validation no longer happens (it happens at
runtime).
A consequence of this commit is that Wasmtime will have no built-in way
to reject modules at compile time if they'll fail to be instantiated
within a particular pooling allocator configuration. Instead a module
must attempt instantiation see if a failure happens.
* Fix benchmark compiles
* Fix some doc links
* Fix a panic by ensuring modules have limited tables/memories
* Review comments
* Add back validation at `Module` time instantiation is possible
This allows for getting an early signal at compile time that a module
will never be instantiable in an engine with matching settings.
* Provide a better error message when sizes are exceeded
Improve the error message when an instance size exceeds the maximum by
providing a breakdown of where the bytes are all going and why the large
size is being requested.
* Try to fix test in qemu
* Flag new test as 64-bit only
Sizes are all specific to 64-bit right now
Without async fuzzing, we won't be able to test the most interesting
aspects of epoch interruption, namely the
interrupt/update-deadline/resume flow. However, the "trap on epoch
change" behavior works even for synchronous stores, so we can fuzz with
this the same way we fuzz with the interrupt flag.
* fuzzing: Add a custom mutator based on `wasm-mutate`
* fuzz: Add a version of the `compile` fuzz target that uses `wasm-mutate`
* Update `wasmparser` dependencies
* Enable copy-on-write heap initialization by default
This commit enables the `Config::memfd` feature by default now that it's
been fuzzed for a few weeks on oss-fuzz, and will continue to be fuzzed
leading up to the next release of Wasmtime in early March. The
documentation of the `Config` option has been updated as well as adding
a CLI flag to disable the feature.
* Remove ubiquitous "memfd" terminology
Switch instead to forms of "memory image" or "cow" or some combination
thereof.
* Update new option names
Ended up being a routine update but seemed good to go ahead and hook up
updates. While I was at it I went ahead and hooked up multi-value
swarm fuzzing as well now that wasm-smith implements it.
* Enable SSE 4.2 unconditionally
Fuzzing over the weekend found that `i64x2` comparison operators
require `pcmpgtq` which is an SSE 4.2 instruction. Along the lines of #3816
this commit unconditionally enables and requires SSE 4.2 for compilation
and fuzzing. It will no longer be possible to create a compiler for
x86_64 with simd enabled if SSE 4.2 is disabled.
* Update comment
In #3820 we see an issue with the new heuristics that control use of
memfd: it's entirely possible for a reasonable Wasm module produced by a
snapshotting system to have a relatively sparse heap (less than 50%
filled). A system that avoids memfd because of this would have an
undesirable performance reduction on such modules.
Ultimately we should try to implement a hybrid scheme where we support
outlier/leftover initializers, but for now this PR makes the "always
allow dense" limit configurable. This way, embedders that want to ensure
that memfd is used can do so, if they have other knowledge about the
maximum heap size allowed in their system.
(Partially addresses #3820 but let's leave it open to track the hybrid
idea)
This commit fixes the spectests fuzz target to set a lower bound on the
arbitrary pooling allocator configurations of 10 memory pages so that the limit
doesn't interfere with what's required in the spec tests.
Per-`Store` allocations are already limited with the `StoreLimits`
structure while fuzzing to ensure fuzz targets don't allocate more than
1GB of memory, but the `instantiate-many` fuzzer created many separate
stores which each had their own limit, meaning that the 2GB limit of
fuzzing could be pretty easily reached.
This commit fixes the issue by making `StoreLimits` a shareable type via
`Rc` to ensure the same limits can be applied to all stores created
within a fuzz run, globally limiting the memory even across stores to 1GB.
In #3800 I added support to consume fuzz input as selection of whether
or not target features should be enabled. This was done in a
platform-specific manner, however, which means that I can no longer
reliably take the fuzz reproducer cases from oss-fuzz and reproduce them
locally on an aarch64 machine. This commit fixes this problem by
unconditionally pulling bytes from the input for fuzz features,
irrespective of the host platform. Features are then discarded if
they're not applicable.
* Unconditionally enable sse3, ssse3, and sse4.1 when fuzzing
This commit unconditionally enables some x86_64 instructions when
fuzzing because the cranelift backend is known to not work if these
features are disabled. From discussion on the wasm simd proposal the
assumed general baseline for running simd code is SSE4.1 anyway.
At this time I haven't added any sort of checks in Wasmtime itself.
Wasmtime by default uses the native architecture and when explicitly
enabling features this still needs to be explicitly specified.
Closes#3809
* Update crates/fuzzing/src/generators.rs
Co-authored-by: Andrew Brown <andrew.brown@intel.com>
Co-authored-by: Andrew Brown <andrew.brown@intel.com>
This commit improves the stability of the fuzz targets by ensuring the
generated configs and modules are congruent, especially when the pooling
allocator is being used.
For the `differential` target, this means both configurations must use the same
allocation strategy for now as one side generates the module that might not be
compatible with another arbitrary config now that we fuzz the pooling
allocator.
These changes also ensure that constraints put on the config are more
consistently applied, especially when using a fuel-based timeout.
* Fuzz cranelift cpu flag settings with Wasmtime
This commit updates the `Config` fuzz-generator to consume some of the
input as configuration settings for codegen flags we pass to cranelift.
This should allow for ideally some more coverage where settings are
disabled or enabled, ideally finding possible bugs in feature-specific
implementations or generic implementations that are rarely used if the
feature-specific ones almost always take precedent.
The technique used in this commit is to weight selection of codegen
settings less frequently than using the native settings. Afterwards each
listed feature is individually enabled or disabled depending on the
input fuzz data, and if a feature is enabled but the host doesn't
actually support it then the fuzz input is rejected with a log message.
The goal here is to still have many fuzz inputs accepted but also ensure
determinism across hosts. If there's a bug specifically related to
enabling a flag then running it on a host without the flag should
indicate that the flag isn't supported rather than silently leaving it
disabled and reporting the fuzz case a success.
* Use built-in `Unstructured::ratio` method
* Tweak macro
* Bump arbitrary dep version
This commit makes it such that the pooling allocator will be configured with a
much lower upper bound for memory pages, which will greatly reduce the
likelihood that the fuzzer memory limits will be hit from having too many
memories from too many instances committed.
* Add the instance allocation strategy to generated fuzzing configs.
This commit adds support for generating configs with arbitrary instance
allocation strategies.
With this, the pooling allocator will be fuzzed as part of the existing fuzz
targets.
* Refine maximum constants for arbitrary module limits.
* Add an `instantiate-many` fuzz target.
This commit adds a new `instantiate-many` fuzz target that will attempt to
instantiate and terminate modules in an arbitrary order.
It generates up to 5 modules, from which a random sequence of instances will be
created.
The primary benefactor of this fuzz target is the pooling instance allocator.
* Allow no aliasing in generated modules when using the pooling allocator.
This commit prevents aliases in the generated modules as they might count
against the configured import limits of the pooling allocator.
As the existing module linking proposal implementation will eventually be
deprecated in favor of the component model proposal, it isn't very important
that we test aliases in generated modules with the pooling allocator.
* Improve distribution of memory config in fuzzing.
The previous commit attempted to provide a 32-bit upper bound to 64-bit
arbitrary values, which skewed the distribution heavily in favor of the upper
bound.
This commit removes the constraint and instead uses arbitrary 32-bit values
that are converted to 64-bit values in the `Arbitrary` implementation.
In working on #3787 I see now that our coverage of loading precompiled
files specifically is somewhat lacking, so this adds a config option to
the fuzzers where, if enabled, will round-trip all compiled modules
through the filesystem to test out the mmapped-file case.
This commit updates the `memfd` support in Wasmtime to have a runtime
toggle as to whether it's used or not. The compile-time feature gating
`memfd` support is now also re-enabled by default, but the new runtime
switch is still disabled-by-default.
Additionally this commit updates our fuzz oracle to turn on/off the
memfd flag to re-enable fuzzing with memfd on oss-fuzz.
This fixes a bug in the memfd-related management of a linear memory
where for dynamic memories memfd wasn't informed of the extra room that
the dynamic memory could grow into, only the actual size of linear
memory, which ended up tripping an assert once the memory was grown. The
fix here is pretty simple which is to factor in this extra space when
passing the allocation size to the creation of the `MemFdSlot`.
